Bi-injected cap, and method for manufacturing such a cap

ABSTRACT

The disclosure includes a cap having a first portion made of a plastic material and forming a bottom for covering a container neck and a protective side wall for surrounding the container neck, and a second portion made of a flexible material that is compatible with the plastic material of the first portion and separate from the plastic material of the first portion, the second portion being annular and consisting of a flexible seal, which projects from the bottom toward the interior of the side wall and which is welded to the first portion. Thus, the manufacture of the stopper by molding includes injecting a flexible material to produce the flexible annular seal and then the movable portions of the mold are placed such that the flexible material is in a groove that is set back from the planar surface of the mold.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a National Phase Entry of International ApplicationNo. PCT/EP2012/055576, filed on Mar. 29, 2012, which claims priority toFrench Patent Application Serial No. 1100925, filed on Mar. 29, 2011,both of which are incorporated by reference herein.

TECHNICAL FIELD

The invention relates to a bi-injected cap, and more specifically, to abi-injected cap integrating a flexible seal.

BACKGROUND

Caps are known provided with a bottom, a threaded side wall intended tobe screwed on a container neck, and a primary annular sealing skirtprotruding from the bottom and positioned radially inside the side wall,said skirt being intended to bear radially against a cylindrical innerwall of the neck of the container. According to document WO 98 035 881by the applicant, this inner side wall may include an annular contactbead with the neck, said bead being situated in a free end portion ofthe sealing skirt and turned radially outward to allow good control ofthe point of contact with the neck. So as also to control the contactpressure between the skirt on the neck, it is possible to give the skirta generally tapered shape, flaring from the bottom toward the free end,as described in application WO 2005/077777. It is also possible toprovide for curving the end of the skirt, as suggested in document FR2,900,908.

The sealing obtained with this type of cap is excellent, but the contactline ensuring sealing is situated inside the neck, away from the upperrim of the neck. The threaded outer side wall and the bottom of the capalso provide protection for the assembly of the end of the neck fromdust or contaminants. Under certain extreme storage conditions, however,it has been observed that contaminants or pollution may propagate fromthe outside, passing through the threaded interface between the cap andthe neck, as far as the rim thereof.

To combat these outside contaminations, it is possible to position oneor more secondary annular sealing skirts radially between the inner faceof the side wall and the primary sealing skirt and intended to bear onthe rim of the neck the container, as proposed in document EP 1,600,394.However, when the cap is completely molded from plastic material, it isparticularly delicate to dimension the secondary skirts so as to givethem a sufficient elasticity to obtain the desired barrier effect. Thistype of fine secondary skirt is well suited to smooth necks, but doesnot accommodate necks with an imperfect geometry very well.

In application WO 08 012 426 it was proposed, to improve the sealing ofa threaded covering cap traditionally including a bottom, an inwardlythreaded side wall and a tamperproof strip at the end of the side wall,to combine several sealing means, and in particular: an inner annularsealing skirt protruding from the bottom of the cap to come into contactwith an inner cylindrical wall of the neck, an outer annular sealingskirt, positioned radially outside the inner sealing skirt, protrudingfrom the bottom of the cap to ensure contact with an outer wall of therib of the neck of the container, an additional annular skirt positionedaxially between the inner thread of the side wall of the cap and thetamperproof strip, protruding radially toward the inside and axiallytoward the tamperproof strip, the additional skirt being intended tobear elastically against a collar of the neck of the container, and anannular seal covering the portion of the bottom situated between theinner skirt and the outer skirt, and which bears on the upper rim of theneck of the bottle. It is provided that the seal, preferably made fromthermoplastic elastomer (TPE), can be applied either a posteriori on ajoiner machine, or bi-injected with the cap. However, no bi-injectionmethod is described and, in practice, the bi-injection of such a capposes technical problems.

Also known, in another context, are bi-material caps including a firstportion made from a plastic material forming a bottom, a side wallprotecting a container neck, and a second portion made from a flexiblematerial, in particular thermoplastic elastomer (TPE), compatible withthe plastic material of the first portion, that second portionconstituting an annular sealing skirt positioned radially inside theside wall. In document EP 1,373,086, a technique is proposed forattaching such a seal on the bottom of a cap, by pouring or molding thematerial of the seal on the bottom provided with catching protrusionsfor example having a dovetail profile. The control of the bi-injectionmethod for such caps is delicate. To prevent the flexible materialmaking up the seal from being driven during injection of the plasticmaterial forming the first portion of the cap, it is necessary to waitfor the seal to cool.

SUMMARY

According to a first aspect of the invention, the invention aims to forma bi-material cap provided with a seal. To that end, proposed accordingto this first aspect of the invention is a cap including:

-   -   a first portion made of a plastic material and forming a bottom        for covering a container neck and a protective side wall for        surrounding the container neck, and    -   a second portion made of a flexible material that is compatible        with the plastic material of the first portion and separate from        the plastic material of the first portion, the second portion        being annular and consisting of a flexible seal, which projects        from the bottom toward the interior of the side wall and which        is welded to the first portion.        Compatible here means that the materials adhere to one another        chemically and are therefore welded during overmolding.

According to one important aspect of the invention, the first portionmay include an annular protuberance projecting from the bottom, thesecond portion being welded to the annular protuberance. Thus, duringthe manufacture of the cap by molding, several successive steps arecarried out: first, flexible material is injected so as to form theannular flexible seal. Then, the moving portions of the mold are placedsuch that the flexible material is in a groove, withdrawn relative tothe planar face of the mold, which will define the interior face of thebottom of the cap. During the injection of the plastic material in themold, the plastic material fills the available volume in the grooveabove the flexible material. The groove guarantees the integrity of thegeometry of the interface between the two materials. It is thus possibleto perform the two successive injections at a high temperature, meltingthe interface, which allows good welding between the two materials,while preserving the integrity of the geometry of the portion made fromflexible material. The axial thickness of the protuberance is preferablygreater than 0.10 mm.

According to different alternative embodiments, the cap may have one ormore of the following features:

-   -   the flexible material may be an elastomer material, in        particular a thermoplastic elastomer material.    -   the plastic material may be a thermoplastic, in particular a        polyethylene, polypropylene, polyethylene terephthalate (PET) or        a PLA.    -   the side wall may include an inner thread to screw on an outer        thread of the neck of the container.    -   a primary annular sealing skirt protruding from the bottom and        positioned radially inside the side wall may equip the cap, said        skirt being intended to bear radially against an inner        cylindrical wall of the neck of the container, the flexible seal        being positioned radially between the side wall and the primary        sealing skirt;    -   the distance measured radially between the primary sealing skirt        and the flexible seal, measured in a plane perpendicular to the        axis of revolution of the side wall at 1 mm from the bottom of        the wall, is preferably greater than 0.5 mm, which characterizes        the minimum thickness of the wall of the metal core defining the        cavity of the mold, the outer wall of the primary sealing skirt;    -   the primary sealing skirt may include an annular bead in contact        with the neck, said bead being located in a free end portion of        the sealing skirt and turned radially outward to make it        possible to control the point of contact with the neck well;    -   so as also to control the contact pressure between the primary        skirt and the neck, it is possible to give the skirt a generally        tapered shape, flaring from the bottom toward the free end;    -   inasmuch as the primary skirt serves to interfere with an inner        cylindrical wall of the neck whereas the flexible seal serves to        rest on the upper edge of the neck, it is advantageous, before        placement of the cap on the neck, for the geometric cylinder        with the smallest diameter and which outwardly envelops the        primary sealing skirt to have an intersection with the flexible        seal;    -   the protruding wall of the flexible seal may have a half-circle        or half-ellipse profile or a square, rectangular or trapezoidal        profile, to form a suitable contact surface for the rim of the        neck;    -   the side wall of the cap may be equipped with a tamperproof        ring, connected to the body of the side wall by a frangible        annular zone, for example made by a thin continuous annular        connecting wall between the ring and the side wall or by        bridges, said bridges being obtained either by molding or by        cutting;    -   in that case, it is advantageous for the portion of the primary        sealing skirt intended to come into contact with the neck of the        container and the free end of the flexible seal intended to come        into contact with the rim of the neck of the container to be        situated axially at a distance from one another that is greater        than the elongation at break of the frangible zone.

According to another embodiment of the invention, the bottom of the capmay be provided with a pour spout and form a part of a cap assemblyfurther including a cover, the spout being able to be sealed directly bythe cover or by a to-and-fro valve. In that case, the bottom of the capis not necessarily completely flat, but only over its outer annularperiphery cooperating with the neck of the container, i.e., in theportion including the side wall, the flexible seal and, if applicable,the primary sealing skirt. According to another aspect of the invention,the invention relates to a container provided with a neck closed by acap as previously described, the flexible seal of the cap bearingaxially on the upper rim of the neck. In the event the cap includes aprimary sealing skirt, the latter bears radially on an inner cylindricalwall of the neck.

According to another aspect of the invention, the invention relates to amethod for molding a cap including at least one bottom, a side wall andan annular seal, including the following steps:

-   -   two parts of the mold, mobile relative to one another, are        placed so as to form an annular cavity with an injection        orifice; a first of these parts having an annular protuberance,        the annular protuberance defining an upper wall of the annular        cavity, the other part having an annular groove defining a lower        wall of the annular cavity, the annular protuberance penetrating        the annular groove so as to close the annular cavity;    -   a flexible material is injected into the annular cavity so as to        fill the annular cavity,    -   the two parts of the mold are separated from each other so as to        form a primary cavity having a first portion intended to form        the bottom of the cap, extended by a second, generally        cylindrical portion intended to form the side wall of the cap,        the first portion having an inner wall defining the inner face        of the bottom of the cap, the annular cavity containing the        flexible material emerging in the first portion of the primary        cavity.

Preferably, the injection of the plastic material in the mold is donethrough an injection orifice aligned with the axis of symmetry ofrevolution of the annular cavity, which ensures symmetrical filling ofthe cavity and avoids potential problems of ovality of the cap. Theflexible material is injected in the annular cavity through an injectionorifice that is offset relative to the axis of symmetry. Certain“traces” of the method are visible on the finished cap: inasmuch as thefirst part forms the upper (outer) face of the bottom of the cap, thatupper face has an annular groove that is the imprint of the annularprotuberance of the first part, said groove being located at theflexible annular seal. Furthermore, if applicable, it is possible to seethe traces of the injection orifices. The first portion of the primarycavity may be configured for a cap with a substantially flat bottom, orfor cap whereof the bottom forms a spout.

BRIEF DESCRIPTION OF THE DRAWINGS

Other features and advantages of the invention will emerge from readingthe following description, in reference to the appended figures, whichillustrate:

FIG. 1, a cross-sectional view of a cap according to one embodiment ofthe invention, mounted on a container neck;

FIG. 2, a detail of the cap of FIG. 1;

FIG. 3, a diagrammatic view of the positioning of the parts of a moldfor manufacturing the cap of FIGS. 1 and 2, in a first injection phase;

FIG. 4, a diagrammatic view of the positioning of the parts of the moldfor manufacturing the cap of FIGS. 1 and 2, in a second injection phase;and

FIG. 5, a cross-sectional view of a detail of one alternativeembodiment.

DETAILED DESCRIPTION

FIGS. 1 and 2 show a cap 10 made up of two parts, one made from plasticintended to form an outer enclosure 12 of the cap and the other madefrom a flexible material, forming an annular seal 14 welded to theinside of the first part. More specifically, the enclosure 12 of thecap, in a single piece, includes a discoid bottom 16, an outer side wall18 bearing an inner thread 20, a tamperproof ring 22 extending the freeend 24 of the side wall 18 connected to the latter by material bridges26, and a tapered sealing skirt 28 positioned inside the outer side wall18, protruding from the bottom 16 and flaring as it moves away from thebottom 16. The sealing skirt 28 is provided with a bulge 30 at its end.An annular volume 32 is delimited between the outer side wall 18, thesealing skirt 28 and the bottom 16. The flexible seal 14 is positionedin this inner volume 32.

In FIG. 1, the cap is screwed on the neck 36 of the container, said necktraditionally including a lower collar 38 serving for handling of thecontainer, a fastening collar 40 on which the tamperproof ring 22 isfastened, and an outer thread 42 cooperating with the inner thread 20 ofthe cap for screwing and unscrewing of the latter. As shown in FIG. 1,the inner volume 32 delimited by the side wall 18, the sealing skirt 28and the bottom 16 of the cap constitutes a housing for the free end ofthe neck 36. The sealing skirt 28 bears radially with interference on acylindrical inner wall 44 of the neck. The contact pressure between theskirt 28 and the neck 36 is completely controlled owing to the geometryof the bulge 30 of the skirt, the axial section of which is an arc ofcircle in the vicinity of the point of contact. The seal 14 bears on theupper rim 46 of the neck. The radial thickness of the seal 14 may berelatively significant, in the same order of magnitude as its largestaxial thickness, and preferably greater than half of the thickness ofthe wall of the neck 36. The free face of the seal, turned toward theinside of the annular volume 32, may have an arc of circle section. Thedimensional interference with the neck in the closed position ensures alarge contact surface and high contact pressure by crushing of the seal14. Inasmuch as the purpose of the sealing skirt is to interfere withthe inner cylindrical wall of the neck whereas the flexible seal isintended to rest on the upper edge of the neck, it is advantageous,before screwing on the neck, for the geometric cylinder with thesmallest diameter that outwardly envelops the primary sealing skirt tohave an intersection with the flexible seal.

As shown in FIG. 2, the inner face of the bottom, in the annular volume32, has two annular grooves 48, 50 separated by an annular protuberance52 protruding axially inside the volume 32. These two annular grooves,one radially inner 48, located between the protuberance 52 and the skirt28, the other radially outer 50, situated between the protuberance 52and the side wall 18, each have a substantially planar face. Theprojecting face 55 of the protuberance is also substantially planar andlocated away from the groove bottoms, as illustrated by dimension X inFIG. 2. This projecting face 55 constitutes a weld interface for theflexible seal, which is consequently completely situated at a minimalaxial distance X from the bottom of the grooves 48, 50.

The outer face 56 of the bottom has an annular groove 58 situated at theprotuberance 52 and the flexible annular seal 14. This groove isradially bordered on either side by planar facets 60, 62. The profile ofthe groove 58 and the planar facets 60, 62 corresponds negatively to theprofile of the protuberance 52 and the grooves 48, 50 of the inner faceof the bottom situated in the annular volume 32.

The advantages of the protuberance will better appear in the followingdescription of the manufacturing method for manufacturing the cap,illustrated diagrammatically in FIGS. 3 and 4. The injection mold ismade up of at least two parts movable relative to one another. One ofthe parts is a stationary block 100 that forms the majority of the outersurface of the cap, and in particular the portion of the outer surfaceof the bottom of the cap situated across from the annular volume 32. Thestationary block 100 in particular includes surfaces for producing thegroove and the flats, and in particular a protuberance 102 fitting theshapes of the groove 58 and two planar facets 104, 106 on either side ofthe protuberance 102, to produce the facets 60, 62 of the outer face ofthe bottom 16 of the cap.

The other part is a core 108 that in particular forms the outer surfaceof the assembly of the cap 10, and more specifically the inner surfaceof the finished cap, i.e., the assembly formed by the enclosure 12 andthe flexible seal 14. The core 108 therefore includes an annular groove110 corresponding to the cavity of the flexible seal 14 and theprotuberance 52 and two flat facets 112, 114 on either side of thegroove 110, to produce the bottoms of the grooves 48, 50. It alsoincludes a substantially tapered face 115 defining the outer wall of theprimary seal 28. It should be noted that the shortest distance Y betweenthe walls 110 and 115 must be sufficient to avoid making the core 108fragile. In practice, the smallest distance Y is greater than thedistance X.

In a first molding phase illustrated in FIG. 3, the core 108 ispositioned in contact with the stationary block 100. The protuberance102 partially penetrates the annular groove 110 to close ithermetically, while preserving an annular cavity 116 in the shape of theflexible seal. A flexible material is injected into the annular cavityso as to fill the annular cavity and form the seal. The injection hole118 is located in the protuberance of the block.

At the end of this first phase, the two portions 100, 108 of the moldare moved away from each other so as to form a primary cavity whereofthe imprint corresponds to the shape of the finished cap, the groovealready being filled by the flexible seal, as illustrated in FIG. 4.More specifically, the cavity has a portion with a generally discoidshape intended to form the bottom of the cap, extended by a generallycylindrical portion intended for the side wall of the cap, the generallydiscoid portion having an inner wall defining the inner face of thebottom of the cap, the annular cavity containing the flexible materialemerging in the discoid part of the primary cavity.

The plastic material will then be injected through a central injectionhole. As illustrated in FIG. 4, the flexible material forming the jointis situated in a protected region of the mold, relative to the deviationof the flow of injected plastic material. This is due to the fact thatthe groove of the core of the mold that contains the flexible materialof the seal has not been completely filled by the latter in the firstinjection phase. The arrows in FIG. 4 show the path of the plasticmaterial during its injection. The groove protects the flexible materialof the seal from the flow of plastic material, which prevents part ofthe flexible material from being carried away toward other parts of themold. It is therefore possible to inject plastic material on theflexible material making up the seal while ensuring melting at theinterface without deteriorating the geometric integrity of the seal.

The separation between the two parts of the mold corresponds to thethickness of the plastic material forming the bottom 16 of the cap.Characteristically, the thickness of plastic material is constant in theannular region of the bottom, which limits the annular cavity 32,between the sealing skirt 28 and the outer side wall 18. In the finalphase, the bi-material cap is ejected by removing the core. It will beunderstood the groove 58, which has no specific function, results fromthe manufacturing method, since it is the imprint of the protuberance102. Its depth is equal to the height X of the protuberance 52.

According to the alternative embodiment shown in FIG. 5, the annularseal 14 is configured so as to have a substantially planar annularcontact surface with the upper rim of the neck of the container. Thisplanar surface guarantees additional stability of the seal on the rim ofthe neck during screwing. In this example embodiment, the seal 14 has,in cross-section, a substantially square surface, the interface weldedto the enclosure 12 being planar, parallel and with a dimensionsubstantially identical to the planar annular contact surface intendedto come into contact with the rim of the neck of the container.

Other seal section shapes, rectangular or more generally polygonal, canbe considered, for example a trapezoidal shape. In this hypothesis, thetrapezoid may be oriented with a small base serving as contact surfacewith the container neck and its large base serving as interface with theenclosure 12 of the cap, or conversely undercut with a small base on theinterface side and large base serving as contact surface with thecontainer, to form a dovetail seal. In the latter hypothesis, the angleof the trapezoid is preferably smaller than 10°, and preferably smallerthan 5°.

Naturally, many other alternatives are possible. The weld interface withthe flexible seal may be oblique, such that the thickness of the seal,measured between the weld interface and the free face, is not constant.The section of the seal is then a convex quadrilateral. Such anarrangement may allow better adaptation to necks with asymmetricalsections. More generally, the weld interface may be non-planar. Theprofile of the protuberance may assume various non-polygonal shapes. Theprofile of the grooves may differ from that of the example embodiment.The plastic part may be a spout, covered by a cover connected to thespout for example by a hinge or strap. The cover may be connected on thespout or form a single piece therewith.

1. A cap comprising: a first portion made of a plastic material, forminga bottom for covering a container neck and a protective side wall forsurrounding the container neck, the first portion including two annulargrooves separated by an annular protuberance; and a second portion madeof a flexible material that is compatible with the plastic material ofthe first portion and separate from the plastic material of the firstportion, the second portion being annular and consisting of a flexibleseal, which projects from the bottom toward the interior of the sidewall and which is welded to the first portion, the second portion beingwelded to the annular protuberance.
 2. (canceled)
 3. The cap of claim 1,wherein the flexible material is an elastomer material.
 4. The cap ofclaim 1, wherein the plastic material is a thermoplastic.
 5. The cap ofclaim 1, wherein the side wall includes an inner thread to screw on anouter thread of the neck of the container.
 6. The cap of claim 1,wherein the first portion forms a primary annular sealing skirtprotruding from the bottom and positioned radially inside the side wall,the primary sealing skirt being intended to bear radially against aninner cylindrical wall of the neck of the container, the flexible sealbeing positioned radially between the side wall ( and the primarysealing skirt.
 7. The cap of claim 6, wherein the distance between theprimary sealing skirt and the flexible seal, measured radially in aplane perpendicular to the axis of revolution of the side wall, tangentto a weld face between the annular protuberance and the second portion,is greater than 0.5 mm.
 8. The cap of claim 6, wherein the primarysealing skirt includes an annular bead in contact with the neck, saidbead being located in a free end portion of the sealing skirt and turnedradially outward.
 9. The cap of claim 6, wherein the primary sealingskirt has a generally flared shape from the bottom toward the free end.10. The cap of claim 6, wherein before placement of the cap on the neck,a geometric cylinder which outwardly envelops the primary sealing skirtand has the smallest diameter possible has an intersection with theflexible seal.
 11. The cap of claim 1, wherein the flexible seal has ahalf-circle or half-ellipse profile or a square, rectangular ortrapezoidal profile.
 12. The cap of claim 1, wherein the side wall ofthe cap is equipped with a tamperproof ring, connected to the body ofthe side wall by a frangible annular zone.
 13. The cap of claim 12,wherein the first portion forms a primary annular sealing skirtprotruding from the bottom and positioned radially inside the side wall,the primary sealing skirt being intended to bear radially against aninner cylindrical wall of the neck of the container, the flexible sealbeing positioned radially between the side wall and the primary sealingskirt, and wherein the portion of the primary sealing skirt intended tocome into contact with the neck of the container and the free end of theflexible seal intended to come into contact with the rim of the neck ofthe container are situated axially at a distance from one another thatis greater than the elongation at break of the frangible zone.
 14. Thecap of claim 1, wherein the bottom of the cap is provided with a pourspout and forms a part of a cap assembly further including a cover thatcovers the spout.
 15. A container provided with a neck closed by the capof claim 1, wherein the flexible seal of the cap bears on the neck. 16.A method for molding a cap including at least one bottom, a side walland an annular seal, the method comprising: two parts of the mold,movable relative to one another, are placed so as to form an annularcavity with an injection orifice; a first of these parts having anannular protuberance, the annular protuberance defining an upper wall ofthe annular cavity, the other part having an annular groove defining alower wall of the annular cavity, the annular protuberance penetratingthe annular groove so as to close the annular cavity; a flexiblematerial is injected into the annular cavity so as to fill the annularcavity; and the two parts of the mold are separated from each other soas to form a primary cavity having a first portion intended to form thebottom of the cap, extended by a second, generally cylindrical portionintended to form the side wall of the cap, the first portion having aninner wall defining the inner face of the bottom of the cap, the annularcavity containing the flexible material emerging in the first portion ofthe primary cavity.
 17. The molding method of claim 16, wherein theinjection of the plastic material in the mold is done through aninjection orifice aligned with the axis of symmetry of revolution of theannular cavity.
 18. The cap of claim 3, wherein the flexible material isa thermoplastic elastomer material.
 19. The cap of claim 4, wherein theplastic material is one of: a polyethylene or a polypropylene.